Successive Transmit Beamforming Methods for Multiple-Antenna Orthogonal Frequency Division Multiplexing (ofdm) Systems

1. A method of transmitting beamforming between a transmitter and a receiver in an orthogonal frequency division multiplexing (OFDM) wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using less than complete knowledge of a plurality of previous fading blocks for each of the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for each of the subcarriers by correlating inter-frame and/or inter-subcarrier signals among the plurality of subcarriers, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.

2. The method of claim 1 where performing successive beamforming for each of the plurality of subcarriers comprises independently performing successive beamforming for each of the plurality of subcarriers.

3. The method of claim 1 further comprising determining a fading parameter α at the transmitter or receiver by monitoring a mobile Doppler frequency.

4. The method of claim 1 where performing successive beamforming using less than complete knowledge of the previous fading blocks by beamforming an adaptive codebook design of a current fading block comprises generating a best estimated channel direction {tilde over (g)} t based on the past channel inputs for each subcarrier.

5. The method of claim 1 where performing successive beamforming using less than complete knowledge of the previous fading blocks by beamforming an adaptive codebook design of a current fading block comprises optimizing the adaptive codebook design for each subcarrier by satisfying C opt = arg ⁢ ⁢ max ∀ C ⁢ min ∀ i ≠ j ⁢ 1 -  c i H ⁢ c j  2 , where Copt is the optimum codebook.

7. The method of claim 6 where generating the adaptive codebook comprises generating a single universal constant codebook {circumflex over (F)}={{circumflex over (f)} i , i=1, . . . , 2 N } by solving an optimization problem: F ^ = arg ⁢ min ∀ F ^ ⁢ max 1 ≤ i , ⁢ j ≤ 2 N ⁢ Re ⁡ ( f ^ i H ⁢ f ^ j ) , wherein the codebook {circumflex over (F)} consists of 2 N constant unit norm vectors, where {circumflex over (F)} is calculated offline and stored at both the transmitter and receiver, and where for a different fading parameter α, the codebook is derived by adjusting the scalar parameter η.

9. The method of claim 1 where successive beamforming on M out of the N s subcarriers at each frame in succession, returning to the first subcarrier and repeating comprises: SNR time domain round robin successive beamforming (TDRSBF) to minimize signal-to-noise ratio (SNR) of a received signal given by: S ⁢ ⁢ N ⁢ ⁢ R TDRSBF ≈ E s ⁢ M ⁢ ∑ t = 0 L - 1 ⁢ P t σ 2 ⁢ N s ⁢ ∑ m = 1 N s M ⁢ [ R time 2 ⁡ ( m ) ⁢ ( N t - β ~ steady ⁡ ( N t - 1 ) ) + ( 1 - R time 2 ⁡ ( m ) ) ] , ⁢ ⁢ where ⁢ ⁢ β ~ steady ⁢ = Δ ⁢ 2 - N N t - 1 ⁢ ( 1 - R time 2 ⁡ ( N s M ) ) 1 - 2 - N N t - 1 ⁢ R time 3 ⁡ ( N s M ) .

10. The method of claim 1 where performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on inter-subcarrier correlations for each subcarrier.

12. The method of claim 10 where performing successive beamforming based on inter-subcarrier correlations for each subcarrier comprises: SNR Fourier domain round robin successive beamforming (FDRSBF) to minimize signal-to-noise ratio (SNR) of a received signal given by: S ⁢ ⁢ N ⁢ ⁢ R FDRSBF ≈ E s ⁢ M ⁢ ∑ i = 0 L - 1 ⁢ P t σ 2 ⁢ N s ⁢ ∑ m = 1 N s M ⁢ [ R time 2 ⁡ ( m ) ⁢ ( N t - β ~ steady ⁡ ( N t - 1 ) ) + ( 1 - R time 2 ⁡ ( m ) ) ] , ⁢ ⁢ where ⁢ ⁢ β ~ steady ⁢ = Δ ⁢ 2 - N N t - 1 ⁢ ( 1 - R freq 2 ⁡ ( 1 ) ) 1 - 2 - N N t - 1 ⁢ R freq 2 ⁡ ( 1 ) . ( 28 )

13. The method of claim 1 where performing successive beamforming for each of the plurality of subcarriers comprises: grouping all subcarriers into M clusters, each group consisting of N s /M consecutive subcarriers; successive beamforming across the M clusters at each frame; selecting for each cluster only one beamforming vector that accomplishes the highest worst-case SNR for all subcarriers within the cluster; and generating only N feedback bits for each cluster so that NM bits are generated for the whole frame.

14. The methods of claim 13 where successive beamforming across the M clusters at each frame comprises using both intra-cluster and inter-cluster frequency domain correlations.

15. The methods of claim 13 where successive beamforming across the M clusters at each frame comprises using a beamforming vector that attains the highest worst-case instantaneous SNR for each cluster.

17. The method of claim 1 where performing successive beamforming comprises extracting a corresponding AR1 channel model to describe a time domain and frequency domain channel adaptation on each subcarrier.

18. The method of claim 1 where performing successive beamforming comprises quantifying the inter-frame as well as inter-subcarrier correlations on different subcarriers.

19. The method of claim 1 where performing successive beamforming comprises reducing a feedback requirement by the use of a plurality of round robin and clustering algorithms.

20. The method of claim 1 where performing successive beamforming comprises reducing a number of feedback bits in the OFDM system by using both successive beamforming and round robin/clustering.

21. The method of claim 1 where performing successive beamforming comprises using only a single codebook on both sides of a wireless link.

22. An apparatus for performing the method of claim 1 transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel.

23. A method of transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using less than complete knowledge of a plurality of previous fading blocks for the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for the subcarriers by including time domain mutual correlations in the channel fading, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.

24. A method of transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using less than complete knowledge of a plurality of previous fading blocks for the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for the subcarriers by including frequency domain mutual correlations in the channel fading, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.

25. A method of transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using less than complete knowledge of a plurality of previous fading blocks for the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for the subcarriers by exploiting both the time domain and frequency domain correlations in the channel fading, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.

26. A method of transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using less than complete knowledge of a plurality of previous fading blocks for the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for the subcarriers by using the transmit weight from one of the plurality of previous fading blocks and/or neighboring subcarrier on the current subcarrier in the OFDM system, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.

27. A method of transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using less than complete knowledge of a plurality of previous fading blocks for the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for the subcarriers by constructing a successive beamforming codebook based on the knowledge from one of the plurality of previous fading blocks and/or neighboring subcarrier, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.

28. A method of transmitting beamforming between a transmitter and a receiver in an OFDM wireless system having a plurality of subcarriers for a time varying fading channel comprising: performing successive beamforming for each of the plurality of subcarriers using knowledge of a plurality of previous fading blocks for the subcarriers by beamforming an adaptive codebook, C={c 1 ; . . . ; c 2 N }, of a current fading block for the subcarriers by selecting from a systematic successive codebook design strategy for OFDM systems that provides easy storage, synchronized adaptation, as well as beamforming gains above a predetermined minimum, wherein performing successive beamforming for each of the plurality of subcarriers comprises performing successive beamforming based on interframe correlations within each subcarrier by successively beamforming on M out of the N s subcarriers at each frame in succession until a last subcarrier is reached and returning to the first subcarrier and repeating successive beamforming on M out of the N s subcarriers in a temporal round robin rotation among subcarriers.